An object is to provide an automatic analyzer that prevents an effect of various environmental changes on an equilibrium state of an immunological binding reaction. An automatic analyzer of an embodiment of the invention includes a B/F separation unit that executes a B/F separation step separating an unreacted component and a reacted component from a liquid in which a sample and a reagent are reacted, a detection unit that detects a reacted component in the liquid after the B/F separation step, and a temperature maintaining unit that maintains the B/F separation unit and the detection unit in substantially the same temperature environment.

In an automatic analyzer in which required maintenance can be executed efficiently, without omission, an operation control unit controls operations of an analysis module (ISE, AU1, AU2) including a sample vessel transport mechanism, a reagent vessel transport mechanism, a reaction vessel transport mechanism, a sample dispensing mechanism, and a reagent dispensing mechanism, and of a display unit, and analyzes a sample accommodated in a reaction vessel. The operation control unit stores a validity period for each maintenance item of the analysis module (ISE, AU1, AU2) and an execution time for each maintenance item in a memory, displays an execution time together with an identification representation of execution priority level based on the expiration dates on the display unit, rearranges the display order of the maintenance items on the basis of the execution priority level, in accordance with an operator's instruction inputted through an operation input portion.

A method comprises: aspirating a sample through a needle capillary into a chamber having first and second windows, the capillary and chamber both affixed to a moveable robotic arm; causing a light beam generated by a light source that is affixed to the robotic arm to pass through the sample between the windows; detecting, using a photodetector that is affixed to the robotic arm, a quantity of the light that passes through the sample and the windows; determining an optical absorbance of the sample and a concentration of an analyte in the sample from the detected quantity of light; determining a quantity of the sample to dispense into an analytical apparatus based on the determined concentration; moving the robotic arm so as to cause the needle capillary to mate with an inlet port of an analytical apparatus; and dispensing the determined quantity of the sample into the analytical apparatus.

The invention is a flexible and configurable inspection system for the inspection of container units that combines and integrates a holding assembly for multiple containers integrating servo-controlled rotation of the units, transport and positioning of the containers that simulate human handling, and camera stations employing automated vision inspection. The system performs horizontal inspection for particulate and any other container defect that promotes particulate to better locate within the inspection area of the cameras. Inspection sequences and product recipes combine the typical manual inspection agitation with automated inspection rotational techniques to optimize detection. The system allows for semi-automatic operation with the operator at the front of the station feeding and out-feeding material manually or fully automated with conveyance system feeding and out-feeding material from the back of the station.

A fluid analysis arrangement (1) comprises a particle quantifying device (4), a holder (6), a robot (3), a washing station (5) and a control unit (2). The particle quantifying device (4) has a sensor unit (42) with a sensing stick (421) to be arranged in a fluid to sense for particles in the fluid, and an evaluation unit (41). The holder (6) has a plurality of seats each configured to receive a container in which a sample fluid is arranged. The control unit (2) is connected to the particle quantifying device (4) and the robot (3). The sensor unit (42) is mounted to the robot (3). The control unit (2) is configured to control the robot (3) to arrange the sensing stick (421) in one of the sample fluids of each container received in the seats of the holder (6) after another, activate the particle quantifying device to sense for particles in the sample fluids, and control the robot (3) to arrange the sensing stick (421) in the washing station (5) after each sensing for particles in one of the sample fluids and before arranging the sensing stick (421) in a next one of the sample fluids.

A method of calibrating an imaging device adapted to characterize a feature of a sample container, such as a cap color or cap type. The method includes providing a calibration tube including an imaging surface at an imaging location of a first imaging apparatus; illuminating the imaging surface with light emitted from multiple front light sources; adjusting a drive current to each of the multiple front light sources to establish a substantially uniform intensity of the imaging surface; recording drive current values for the multiple front light sources; replacing the calibration tube with a calibration tool having a calibration surface of a known reflectance; and measuring target intensity values of the calibration tool at the respective drive current values. Calibration tools, imaging apparatus, quality check modules, and health check methods are provided, as are other aspects.

A method is presented. The method comprises establishing, by a communication module, a connection between an instrument data processing module and a laboratory management module via a network; identifying, by a protocol identification module, an instrument communication protocol supported by the instrument data processing module and a laboratory management module communication protocol supported by the laboratory management module; and transmitting, by the communication module, messages from the instrument data processing module to the laboratory management module in the instrument communication protocol when it is determined that the instrument communication protocol is the same as or compatible with the laboratory management module communication protocol and/or transmitting, by the communication module, messages from the laboratory management module to the instrument data processing module in the laboratory management module communication protocol when it is determined that the laboratory management module communication protocol is the same as or compatible with the instrument communication protocol.

Systems and methods for automated cap removal with an autosampler system are described. In an aspect, an autosampler system includes, but is not limited to, a sample rack; a sample vessel stabilizer configured to transition the sample rack between a load/unload state and a lock state; an uncapper supported by a first z-axis support; and a sample probe supported by a second z-axis support, wherein the uncapper is configured to remove a cap from a sample vessel held by the sample rack when the sample rack is in the lock state, and wherein the uncapper is configured to change the position of the removed cap to permit access to an interior of the sample vessel by the sample probe without removing the sample vessel from the sample rack.

A system (1) for detecting an analyte of interest in a sample is disclosed that comprises a measurement chamber (21) for metering the sample and including a defined concentration of an activator (27) causing the generation of a product when interacting with the analyte of interest, a heating element (31) thermally coupled to the measurement chamber, a controller (33) adapted to control the heating element such that the measurement chamber is maintained at a defined temperature (T.sub.d), a sensor (35) adapted to detect said product, a timer (37) adapted to time an interaction time between the sample and the activator; and a processor (39) responsive to the sensor and the timer. The processor is adapted to, upon addition of the sample to the measurement chamber, determine an amount of the analyte of interest in the sample from a sensor signal indicative of an amount of said product in the measurement chamber provided by the sensor prior to termination of said interaction; known interaction kinetics between the analyte of interest and the activator at the defined temperature and the defined concentration; and the interaction time at time of generation of the sensor signal. A method of detecting an analyte of interest in a sample using such a system is also disclosed.

In order to aspire to higher sensitivity in an automatic analysis device, it is important to prevent the mixing of dust and the like in a reaction part in which a sample and a reagent react. The present invention presents an automatic analysis device that is provided with a configuration for making the pressure inside a specific block in the device such as a reaction part, or inside the device become positive. By making the pressure become positive and forming an air flow that flows out from the inside of the reaction part or the device, it is possible to limit, to a certain amount or less, the amount of dust penetrating into the reaction part.